CN103367857B - Harmonic oscillator - Google Patents
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- CN103367857B CN103367857B CN201210093600.8A CN201210093600A CN103367857B CN 103367857 B CN103367857 B CN 103367857B CN 201210093600 A CN201210093600 A CN 201210093600A CN 103367857 B CN103367857 B CN 103367857B
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Abstract
The invention relates to a harmonic oscillator. The harmonic oscillator comprises at least a meta-material sheet layer, wherein each meta-material sheet layer comprises a substrate, and a plurality of artificial microstructures which are attached to the surface of the substrate and made of conductive materials; the plurality of artificial microstructures surround the edge of the surface of the substrate; each artificial microstructure is a sheet-like structure made from the conductive materials; the each artificial microstructure comprises a first base lamella, and a second base lamella and a third base lamella both disposed at one side of the first base lamella; the second base lamellas and the third base lamellas are radially distributed at intervals on the substrate. The harmonic oscillator provided by the invention has the advantages of high dielectric constants and low loss, thereby being suitable for a cavity filter. Compared to traditional harmonic oscillator materials, the provided harmonic oscillator has almost the same or even higher dielectric constants, can reduce the resonant frequency of a filter so as to reduce the size of the filter, and at the same time, the lower loss of the harmonic oscillator helps to reduce the Q value decline amount of the filter.
Description
Technical field
The present invention relates to radio-frequency (RF) component, more particularly, it relates to a kind of harmonic oscillator.
Background technology
Meta Materials (metamaterial), refer in particular to a kind of artificial material for having specific response to electromagnetic field, including substrate and
It is attached to the man-made microstructure composition of periodic arrangement on substrate.Substrate is pressed empty with man-made microstructure identical arrangement rule
It is divided into the base board unit of periodic arrangement one by one, each man-made microstructure and its common structure of accompanying base board unit with intending
Into a material cell, then the Meta Materials can be regarded as by material cell with above-mentioned periodic arrangement.Artificial micro- knot
Structure is usually the silk thread composition of conductive material such as metal and has certain geometric structure, such as I-shaped, these structures
The built-up circuit of electric capacity, inductance can be equivalent in electromagnetic field so that each material cell has different from the equivalent of substrate
Dielectric constant and pcrmeability, therefore by designing the man-made microstructure of given shape Meta Materials can be made to have specific dielectric normal
Number and pcrmeability.The length and width size of man-made microstructure generally within 1/2nd of the electromagnetic wavelength to be responded, preferably
1/10th or less than 1/10th, so that material cell is spatially continuous for electromagnetic wave to the response of electromagnetic wave
's.Certainly, man-made microstructure, can be little as much as possible under conditions of meeting within 1/2nd of wavelength, but generally from
Simplify design, simplify manufacturing procedure, the angle degree of examining of reduces cost, be selected in 1/10th nearby.
Meta Materials can be used in cavity body filter as harmonic oscillator, therefore can be reached by designing man-made microstructure
Improve dielectric constant, the purpose so as to reduce wave filter volume under equal resonant frequency.But existing rectangular array arrangement
Man-made microstructure, although with higher dielectric constant, but by the conductive material especially metal of man-made microstructure itself
Larger eddy-current loss is brought, so as to greatly reduce the Q-value of wave filter, it is impossible to meet on market to the Q of cavity body filter
Value is required.
The content of the invention
The technical problem to be solved in the present invention is that the harmonic oscillator loss done for the above-mentioned Meta Materials of prior art is big
Defect, there is provided a kind of dielectric constant is high and little harmonic oscillator is lost.
The technical solution adopted for the present invention to solve the technical problems is:A kind of harmonic oscillator is constructed, including at least one is surpassed
Sheet of material, each metamaterial sheet includes that substrate is artificial with made by the multiple conductive materials being attached on the substrate surface
Micro structure, and the plurality of man-made microstructure surrounds one week along the edge of the substrate surface, each man-made microstructure is conduction
Laminated structure made by material, including the first substrate and the second substrate positioned at the first substrate side, the 3rd substrate, and
Second substrate, the 3rd substrate are arranged along the substrate spaced radial.
In harmonic oscillator of the present invention, the plurality of man-made microstructure is the center of circle into circumference with the center of substrate surface
Distribution.
In harmonic oscillator of the present invention, the substrate is disc, and middle part is provided with through hole.
In harmonic oscillator of the present invention, the harmonic oscillator includes multiple identical Meta Materials pieces being superimposed
Layer, and the substrate center of each metamaterial sheet is conllinear.
In harmonic oscillator of the present invention, the harmonic oscillator includes multiple identical metamaterial sheets, and each super
The center of sheet of material is conllinear, the man-made microstructure and its arrangement all same on each substrate.
In harmonic oscillator of the present invention, the substrate of the metamaterial sheet is ceramics, the plurality of metamaterial sheet
It is superimposed and is formed integrally by low temperature co-fired technique.
In harmonic oscillator of the present invention, first substrate, the second substrate and the 3rd substrate are square square piece,
And second substrate and the 3rd substrate it is identical.
In harmonic oscillator of the present invention, first substrate, the second substrate and the 3rd substrate are semicircle, corner quilt
The square piece or ellipse of rounding.
In harmonic oscillator of the present invention, the conductive material is copper, silver, indium tin oxide, Al-Doped ZnO, carbon are received
Mitron conductive film or conductive plasticss.
In harmonic oscillator of the present invention, the substrate is by epoxy resin, politef, ferrite or SiO2System
Into.
Implement the harmonic oscillator of the present invention, have the advantages that:The present invention harmonic oscillator have high dielectric constant and
Loss is relatively low, and the wave filter with this harmonic oscillator reduces resonant frequency because dielectric constant is high and then reduces volume, while
There is higher Q-value due to being lost low.
Description of the drawings
Below in conjunction with drawings and Examples, the invention will be further described, in accompanying drawing:
Fig. 1 is that the harmonic oscillator of the present invention applies the structural representation in resonator cavity;
Fig. 2 is the top view of the harmonic oscillator of the first embodiment shown in Fig. 1;
Fig. 3 is the schematic diagram of the harmonic oscillator of second embodiment of the invention;
Fig. 4 is the schematic diagram of the harmonic oscillator of third embodiment of the invention;
Fig. 5 is the schematic diagram of the harmonic oscillator of fourth embodiment of the invention.
Specific embodiment
The present invention relates to a kind of harmonic oscillator, as shown in figure 1, the harmonic oscillator is placed in for preparing wave filter in resonator cavity,
For reducing the resonant frequency of resonator cavity so as to reduce wave filter volume under conditions of equal resonant frequency, and little, Q is lost
Value is high.Resonator cavity generally includes cavity, the chamber lid covered on cavity and the input, the outfan that are mounted on cavity, and Fig. 1 is illustrated
Be chamber 1 that cavity and chamber lid are surrounded.Harmonic oscillator 2 is located in chamber 1, and in order that harmonic oscillator 2 is led to positioned at the middle part of chamber 1
Often also the bottom of harmonic oscillator 2 is provided with electromagnetic wave transparent material support base as made by foam plasticss, aluminium oxide etc..Chamber covers can setting unit
Divide the tuning screw for stretching within the chamber, for the resonant frequency of tuned resonating cavity.
The harmonic oscillator of first embodiment as shown in Figure 1 and Figure 2, including three metamaterial sheets and positioned at metamaterial sheet bottom
Ceramic resonance in portion, each metamaterial sheet is including made by substrate 3 and the multiple conductive materials being attached on the surface of substrate 3
Man-made microstructure 4.Substrate 3 generally selects politef, FR-4, epoxy resin, ferrite, SiO2, the non-metallic material such as ceramics
Material, preferably ceramic because the dielectric constant of ceramic material especially special cermacis is higher, harmonic oscillator can be met to dielectric constant and
Low-loss requirement.Multiple metamaterial sheets can directly be superimposed, also can be by certain preparation technology such as low temperature
Altogether burning technology is formed integrally.
Substrate 3 can be the plate of arbitrary plane shape, and these man-made microstructures 4 are surrounded along the marginal surface of place substrate 3
One week.Here marginal surface, refers to as far as possible away from the surface region of substrate center, the base generally namely near substrate outline
Plate surface, espespecially the position of man-made microstructure 4 cause surface region beyond it to be not enough to place another man-made microstructure
Situation, now best results.Obviously, even if the surface region beyond man-made microstructure can also place another man-made microstructure
Situation, falls within protection scope of the present invention, as long as at least the line at substrate center and the man-made microstructure center is more than the company
Line extends to 1/2nd of the total length of substrate edges.Radial direction as herein described, the as substrate center and substrate side
The direction that edge any point line is located.
According to conventional harmonic oscillator shape, the substrate 3 of the present embodiment is preferably disc, as shown in Fig. 2 disk middle part has
The through hole of the concyclic heart.When harmonic oscillator 2 includes multiple metamaterial sheets, the substrate 3 of each metamaterial sheet is identical, and respectively
The through hole of substrate 3 is concentrically arranged on axle ground, and the man-made microstructure 4 on each substrate 3 has identical structure and arrangement.
In Fig. 2, man-made microstructure 4 has 12, and is formed a circle into circle distribution as the center of circle with the center of circle of substrate 3.Often
Individual man-made microstructure is laminated structure made by conductive material, including the first substrate and positioned at the of the first substrate side
Two substrates, the 3rd substrate, and second substrate, the 3rd substrate arrange along the substrate spaced radial.In the present embodiment, each
Substrate is square square piece, the second substrate and the 3rd substrate is identical and a quarter of about the first substrate.
The size of each man-made microstructure 4 is in sub-wavelength scope, i.e., resonant frequency f of for example known resonator cavity, you can push away
The wavelength X of its electromagnetic field is calculated, then the size of man-made microstructure 4 understands in λ/10 or so according to measuring and calculating, size such as length and width,
The twice of diameter or equivalent diameter (i.e. area is divided by girth) is less than λ/4, while the distance between adjacent two man-made microstructure
Also meet and be less than λ/4, you can it is continuous electromagnetic response characteristic to obtain for electromagnetic wave.In the present embodiment, artificial micro- knot
The size of structure 4 is in λ/50 or so.
Except the shape shown in Fig. 2, first, second, third substrate of man-made microstructure 4 can also be other lamellar knots
Structure, as shown in Figure 3;For example, can be the square shape sheet at the rounded angle in corner, as shown in Figure 3;Can also be semicircle, such as Fig. 4 institutes
Show;Substrate can not be disc, or square, then man-made microstructure 4 is arranged along the edge of square substrate 3, such as Fig. 5 institutes
Show, arrangement mode is arranged into circumference with any as the center of circle, (i.e. one of people but each man-made microstructure is parallel to each other
Making micro structure can be overlapped by translation with another man-made microstructure).
The conductive material for making man-made microstructure 4 is metal such as copper, silver, gold or their compound, it is also possible to right and wrong
Metal such as indium tin oxide, Al-Doped ZnO, carbon nanotube conductive thin film or conductive plasticss.
The substrate 3 for being provided with man-made microstructure 4 is put in resonator cavity as harmonic oscillator 2, due to the conduction material of man-made microstructure 4
Material can form dipole in electromagnetic field, so as to improve the dielectric constant of harmonic oscillator 2;Man-made microstructure more than 4, then whole resonance
The dielectric constant of son 2 is higher;Dielectric constant is higher, it is meant that under conditions of identical resonance frequency is realized, the volume of resonator cavity
What is can done is less, so as to reduces cost.
But as harmonic oscillator, except dielectric constant, also another important parameter, i.e. quality factor, abbreviation Q-value.Q-value is
The loss that harmonic oscillator is brought in resonator cavity is characterized, Q-value is higher, show that loss is less, on the contrary it is bigger.Each man-made microstructure
Effect inside 4 due to electromagnetic field can produce vortex, so as to electromagnetic wave energy is lost, reduce Q-value.Man-made microstructure more than 4, shows
So, caused loss is also bigger.
When resonance intracavity excitation electromagnetic field, most electric fields and magnetic field are all concentrated on inside harmonic oscillator, i.e. harmonic oscillator 2
Internal electric field and magnetic field is most strong, and the field intensity of cavity space other parts is very weak.And inside harmonic oscillator 2, electric field, magnetic field point
Cloth is also uneven, and the position field near intermediate throughholes is powerful, and then field intensity is weaker near the part of outer ledge.Field intensity is big
Position alternating field intensity it is also bigger, otherwise it is less.And under the conditions of man-made microstructure identical, the power of alternating field is determined
The power of vortex is formed in man-made microstructure, alternating field is bigger, vortex is larger, and alternating field is less, vortex is less will not even
Vortex is produced, thus it is also less by the next loss of vortex strip.
Therefore, the present invention is based on Meta Materials Technology design man-made microstructure 4, while and the loss distribution based on harmonic oscillator 2
Man-made microstructure 4 in the traditional metamaterial sheet of adjustment is distributed, by the man-made microstructure of original periodic rectangular array arrangement
It is changed to only arrange one week at the edge of substrate 3.So design and be advantageous in that, using man-made microstructure 4 dielectric constant is improved,
Realize reducing resonator cavity volume under conditions of identical resonance frequency;On the other hand, the larger middle part of harmonic oscillator 2 of field intensity is avoided, and
It is to be arranged in the edge of substrate 3, because substrate edges field intensity is little, caused vortex is little, and then little, the reduction amount of Q-value is lost
It is corresponding smaller.All can be permission as long as the reduction amount of Q-value is just controlled in the reasonable scope.Simultaneously as vortex is produced
Waste and the area of man-made microstructure square be directly proportional, therefore man-made microstructure is divided into after several substrates, in Fig. 1
In shown embodiment, it is assumed that the first substrate is the square that the length of side is a, the length of side of second, third substrate is being approximately a/2 just
It is square, it is assumed that loss factor is f, then the loss before substrate is not divided for f (a × 3a/2)2=9/4fa4, divide the damage after substrate
Consume for f [(a2)2+(a/2)4+(a/2)4]=9/8fa4, therefore the former is the twice of the latter.Although active loss can't be such
Accurately proportionate relationship, but as can be seen here, using the man-made microstructure 4 of the present invention, can effective reduce loss.
In order to verify above-mentioned conclusion, the present invention is emulated to first embodiment.The comparative example for adopting is for without artificial micro-
Ceramic resonance of structure, dielectric constant is the ceramic material that 40, Q-value is 10254, height 10.9mm, external diameter 24mm, internal diameter
6mm, measures resonant frequency for 2.1GHz.
Select external diameter to be also 24mm, ceramic resonance that internal diameter 6mm, high 4.2mm, material are same as described above and three it is logical deep and remote
The metamaterial sheet of same external diameter and internal diameter, respectively high 0.8mm, the first substrate of each man-made microstructure be 2mm × 2mm just
Square copper sheet, the second substrate, the 3rd substrate are the square copper sheet of 0.95mm × 0.95mm, and their thickness is only
0.018mm, is separated by 0.1mm between second, third substrate, gap of first substrate with after between the two is also 0.1mm.Three surpass
Sheet of material is just made by low temperature co-fired (LTCC) technique in preparation process with ceramic resonance and is structure as a whole.Measure this
The resonant frequency of harmonic oscillator is also 2.1GHz, and Q-value is 5298.
That is, in the case where identical resonance frequency is realized, the harmonic oscillator with man-made microstructure of the present invention with it is existing
Pure ceramic resonance is compared, and volume about reduces 44%, and the reduction amount of Q-value is not very big.Due to the size of resonator cavity
It is generally based on length and width and is about 1.5 times of harmonic oscillator external diameter, the Experience Design of high be about harmonic oscillator height 3 times, therefore,
Resonator cavity cavity volume can on year-on-year basis be reduced 44% using the harmonic oscillator of the present invention, material cost and processing can be substantially reduced
Cost.
If above-mentioned man-made microstructure is not according to circle distribution, but line space is arranged into the central point of each man-made microstructure
It is the completely same substrate surface of the mode symmetry arrangement of the rectangular array of 3.1mm for 2.1mm, column pitch, other conditions do not change
Become, then the Q-value of the harmonic oscillator for measuring is 3608, and resonant frequency is 2.0GHz.Although now resonant frequency drops enough low, Q
Value is unsatisfactory for the requirement of resonator cavity, is also not all right.
From data above, using the Meta Materials and man-made microstructure of conventional distribution, although resonant frequency decreases,
But the reduction of Q-value becomes apparent from so that Q-value is unsatisfactory for the requirement of harmonic oscillator;And there is the humorous of man-made microstructure distribution of the invention
Oscillator, resonant frequency can also be reduced to a certain extent, and Q-value reduction amount is not obvious, therefore the harmonic oscillator of the present invention is subtracting
The requirement to being lost is met while little resonator cavity volume.
Embodiments of the invention are described above in conjunction with accompanying drawing, but be the invention is not limited in above-mentioned concrete
Embodiment, above-mentioned specific embodiment is only schematic, rather than restricted, one of ordinary skill in the art
Under the enlightenment of the present invention, in the case of without departing from present inventive concept and scope of the claimed protection, can also make a lot
Form, these are belonged within the protection of the present invention.
Claims (8)
1. a kind of harmonic oscillator, it is characterised in that including at least one metamaterial sheet, each metamaterial sheet includes substrate and attached
Man-made microstructure made by the multiple conductive materials on the substrate surface, and the plurality of man-made microstructure along the base
The edge of plate surface is surrounded one week, each man-made microstructure be laminated structure made by conductive material, including the first substrate and
The second substrate, the 3rd substrate positioned at the first substrate side, and second substrate, the 3rd substrate are along substrate radial direction
It is intervally arranged, first substrate, the second substrate and the 3rd substrate are the semicircle, square piece at the rounded angle in corner or ellipse
Shape.
2. harmonic oscillator according to claim 1, it is characterised in that the plurality of man-made microstructure is with the center of substrate surface
It is the center of circle into circle distribution.
3. harmonic oscillator according to claim 2, it is characterised in that the substrate is disc, and middle part is provided with through hole.
4. harmonic oscillator according to claim 3, it is characterised in that the harmonic oscillator include it is multiple be superimposed it is identical
Metamaterial sheet, and the substrate center of each metamaterial sheet is conllinear.
5. harmonic oscillator according to claim 1, it is characterised in that the harmonic oscillator includes multiple identical Meta Materials
Lamella, and the center of each metamaterial sheet is conllinear, the man-made microstructure and its arrangement all same on each substrate.
6. harmonic oscillator according to claim 5, it is characterised in that the substrate of the metamaterial sheet is ceramics, described many
Individual metamaterial sheet is superimposed and is formed integrally by low temperature co-fired technique.
7. harmonic oscillator according to claim 1, it is characterised in that the conductive material is copper, silver, indium tin oxide, mixes
Aluminum zinc oxide, carbon nanotube conductive thin film or conductive plasticss.
8. harmonic oscillator according to claim 1, it is characterised in that the substrate is by epoxy resin, politef, ferrum oxygen
Body or SiO2Make.
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Effective date of registration: 20210425 Address after: 518057 2 / F, software building, No.9, Gaoxin Middle Road, Nanshan District, Shenzhen, Guangdong Province Patentee after: KUANG-CHI INSTITUTE OF ADVANCED TECHNOLOGY Address before: 518034. A, 18B, CIC international business center, 1061 Mei Xiang Road, Shenzhen, Guangdong, Futian District Patentee before: KUANG-CHI INNOVATIVE TECHNOLOGY Ltd. |
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